An exercise apparatus includes a pair of step-up apparatuses wearable on feet of a user. Each step-up apparatus is configurable between an expanded configuration and a compressed configuration to simulate a selected motion when the user wearing the pair of step-up apparatuses travels by foot. One of the step-up apparatuses moves towards the expanded configuration while the other step-up apparatus moves towards the compressed configuration.
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16. An exercise device, comprising:
a self-expanding sole assembly configurable between an expanded configuration and a collapsed configuration, the sole assembly generates a resistive force as the sole assembly in the expanded configuration moves towards the collapsed configuration and generates an expansion force to move from the collapsed configuration towards the expanded configuration, and the expansion force is substantially less than the resistive force.
19. An exercise device, comprising:
a self-expanding sole assembly configurable between an expanded configuration and a collapsed configuration, the self-expanding sole assembly includes
means for collapsing after a user transfers a substantial portion of the user's weight to the self-expanding sole assembly; and
means for generating a resistive force as the sole assembly in the expanded configuration moves towards the collapsed configuration and generating an expansion force to move the sole assembly from the collapsed configuration towards the expanded configuration.
3. An exercise device, comprising:
a self-expanding sole assembly movable between an expanded configuration and a compressed configuration, the sole assembly comprising:
a lower sole;
an upper sole movable with respect to the lower sole; and
an expansion mechanism that generates a resistive force as the upper sole spaced apart from the lower sole moves towards the lower sole so as to move the sole assembly from the expanded configuration towards the compressed configuration, the expansion mechanism is configured to generate a restoring force that is less than the resistive force and the restoring force is sufficient move the sole assembly from the compressed configuration towards the expanded configuration.
1. An exercise system, comprising:
a pair of step-up apparatuses wearable on feet of a user, wherein each step-up apparatus is configurable between an expanded configuration and a compressed configuration to simulate a selected motion when the user wearing the pair of step-up apparatuses travels by foot, wherein each of the step-up apparatuses is configured to begin collapsing after the user transfers a substantial portion of the user's weight to the step-up apparatus and expands upon removal of the substantial portion of the user's weight without providing any appreciable propelling force, and wherein each step-up apparatus includes a sole assembly having an actuating mechanism operable to move the sole assembly from a collapsed configuration to an expanded configuration, wherein the actuating mechanism has
a first state of operation to provide a first rate of collapse, and
a second state of operation to provide a second rate of collapse.
2. The exercise system of
4. The exercise device of
5. The exercise device of
6. The exercise device of
7. The exercise device of
8. The exercise device of
9. The exercise device of
10. The exercise device of
11. The exercise device of
12. The exercise device of
13. The exercise device of
14. The exercise device of
15. The exercise device of
17. The exercise device of
18. The exercise device of
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This application is a continuation of U.S. patent application Ser. No. 14/102,444 filed Dec. 10, 2013, entitled “EXERCISE APPARATUSES AND METHODS OF USING THE SAME,” which is a continuation of U.S. patent application Ser. No. 12/865,695 filed Nov. 29, 2010, now U.S. Pat. No. 8,617,033, entitled “EXERCISE APPARATUSES AND METHODS OF USING THE SAME,” which claims priority to International Patent Application No. PCT/US2009/032748 filed Jan. 30, 2009, which claims the benefit under 35 U.S.C. § 119(e) of U.S. Provisional Patent Application No. 61/063,256 filed Jan. 31, 2008, each of which is incorporated herein by reference in its entireties.
The present disclosure generally relates to exercise apparatuses, and more specifically, to cardiovascular exercise apparatuses.
Exercise equipment for cardiovascular exercise is often used in gymnasiums or homes. It may be difficult or impossible to use stationary exercise equipment while performing other activities. For example, an individual using a treadmill or an elliptical machine may be unable to perform activities that require mobility, such as many household chores. This inconvenience may deter people with busy schedules from exercising. People also may not exercise because of the travel time to and from sport facilities, hiking trails, gymnasiums, or other workout facilities suitable for performing strenuous cardiovascular exercises that can strengthen and build muscles.
Activities (e.g., running, jogging, and walking) can be performed without utilizing stationary exercise equipment. Running and other high impact activities may be unsuitable for people with arthritis, damaged bones (e.g., bones with stress fractures), damaged joints, or damaged connective tissue. Running may also lead to injuries, tissue damage, and pain/discomfort. For example, chrondromalacia patella (commonly referred to as runner's knee) is a condition that may be caused by running. To minimize trauma to joints or connective tissue, people often perform low impact activities; however, low impact activities, such as walking, often do not provide a desired level of aerobic activity and may be ineffective at strengthening or building muscles.
Exercise apparatuses disclosed herein can be used while performing various activities, such as walking, running, hiking, workout routines, or other normal everyday activities. The exercise apparatuses can be worn on an individual's feet in order to provide a desired exercise program. The exercise program can be designed to simulate various types of motions, strengthen muscles, tone muscles, increase aerobic activity, control impact stresses, or the like. The exercise apparatuses, in some embodiments, simulate climbing stairs while the user walks on generally flat surfaces. The exercise apparatuses can be used while performing numerous types of everyday activities, including housework, gardening, or the like.
In some embodiments, an exercise apparatus includes a pair of wearable exercise devices. Each exercise device is configured to be worn on a foot and is movable between an open configuration and a closed configuration such that the exercise device simulates a selected motion when the user travels by foot. In some embodiments, the exercise devices cooperate to simulate climbing stairs and, thus, may provide many of the same benefits as climbing stairs. Each exercise device, in some embodiments, has a restraint to couple the exercise device to a foot of the user. The user can wear the devices to travel over a wide range of different terrains. In some embodiments, the exercise devices are adjustable to control rates of expansion of the exercise devices, rates of collapse of the exercise devices, and the like. Other parameters (e.g., an amount of travel between an upper sole and a lower sole of an exercise apparatus) can also be adjusted.
One exercise device is worn on the user's right foot and another exercise device is worn on the user's left foot. When the user walks, the exercise device leaving the ground can move to the open configuration. When the user steps onto the open exercise device, the exercise device closes. The users body is raised onto the opened exercise device before the exercise device has closed a significant amount. In this manner, two exercise devices cooperate to simulate a desired up and down motion, even though the user may be traveling along a generally flat surface. The exercise devices do not provide any appreciable propelling force, unlike traditional spring shoes. The user provides substantially all of the energy to move forward, as well as substantially all of the energy to step onto the exercise device. The user has to repeatedly raise his/her body by stepping onto the exercise devices. The devices discloses herein can have restoring forces that are minimized to limit propelling of the user forward and/or upward.
In some embodiments, an exercise device has one or more horizontally mounted energy absorbers, vertically mounted energy absorbers, or diagonally mounted energy absorbers. The exercise device may also have one or more linkage mechanisms. The linkage mechanisms may include one or more scissor joints. Outer parts of the linkage mechanism can be fixed to components of the device, and the ends of the inner portions of the linkage mechanism can have bearings and move along tracks or slots. In some embodiments, ends of energy absorbers are coupled directly to a one-piece or multi-piece sole.
The exercise devices, in some embodiments, are adjustable to select how quickly the devices will compress. Exercise devices can be collapsed for storage in relatively small spaces and can also be operable to limit or stop an exercise routine. For example, a user may want to limit or stop the step-up motion for a short period of time but may not want to remove the exercise devices. The exercise devices can have a locked in or expanded configuration and/or a collapsed configuration.
In some embodiments, a footwear apparatus for simulating climbing stairs while traveling along a generally flat surface includes a shoe main body wearable on a foot of a user, a foot retainer, and a collapsible step-up sole assembly. The sole assembly is coupled to the shoe main body by the foot retainer. The sole assembly includes a rigid elongate lower sole and a rigid elongate upper sole substantially parallel to the lower sole. The upper sole has a toe support region to support the user's toes and a heel support region to support the user's heel. The sole assembly further includes a first pair of rigid members extending transversely between the elongate lower sole and the elongate upper sole. Each of the rigid members has an upper end rotatably coupled to the upper sole and a lower end rotatably coupled to the lower sole. A first pivot pin extends through each of the rigid members. The sole assembly also includes a second pair of rigid members extending transversely between and being rotatably coupled to the lower sole and the upper sole. A second pivot pin extends through each of the rigid members of the second pair. An energy absorber is positioned between the first pair of rigid members and the second pair of rigid members. The energy absorber has an upper end rotatably coupled to the upper sole and a lower end rotatably coupled to the lower sole. The energy absorber is movable from an expanded configuration to a compressed configuration to provide a resistive force to control a rate of collapse of the sole assembly such that a distance between the lower sole and the upper sole is mostly reduced after most of a user's body mass is supported by the sole assembly. An opener assembly expands the sole assembly after the sole assembly has been at least partially collapsed.
The resistive force can be a dampening force that resists motion of the sole assembly. The energy absorber may not provide any appreciable forces when it expands. In some embodiments, the energy absorber resists motion in one direction or two directions. The opener assembly can provide a restoring force to expand the sole assembly. The restoring force can be sufficiently small to allow the sole assembly to collapse under the weight of the user but may be sufficiently large to expand the sole assembly.
In some embodiments, a footwear apparatus for simulating climbing stairs while traveling along a generally flat support surface includes a shoe main body wearable on a foot of a user and a collapsible sole assembly coupled to the shoe main body. The sole assembly includes a lower sole and an upper sole translatable with respect to the lower sole. The upper sole has a toe support region and a heel support region. The sole assembly further includes an adjustable lowering mechanism that provides a resistive force to inhibit collapse of the sole assembly such that a distance between the lower sole and the upper sole is mostly decreased after most of a user's body mass is supported by the sole assembly. An opener assembly is configured to push the upper sole away from the lower sole to expand the sole assembly after the sole assembly has been at least partially collapsed.
In other embodiments, an exercise device comprises a self-expanding sole assembly movable between an expanded configuration and a compressed configuration. The sole assembly comprises a lower sole, an upper sole movable with respect to the lower sole, and an expansion mechanism that generates a resistive force as the upper sole spaced apart from the lower sole moves towards the lower sole so as to move the sole assembly from the expanded configuration towards the compressed configuration. In some embodiments, the expansion mechanism is configured to generate a restoring force that is less than the resistive force to move the sole assembly from the compressed configuration towards the expanded configuration. The restoring force can be less than about 50%, 25%, 10%, or 5% of the maximum resistive force produced during use.
In yet other embodiments, an exercise device comprises a self-expanding sole assembly configurable between an expanded configuration and a collapsed configuration. The sole assembly generates a resistive force as the sole assembly in the expanded configuration moves towards the collapsed configuration and generates an expansion force to move from the collapsed configuration towards the expanded configuration. The expansion force, in some embodiments, is substantially less than the resistive force.
In some embodiments, an exercise system comprises a pair of step-up apparatuses wearable on a user's feet. Each step-up apparatus is configurable between an expanded configuration and a compressed configuration to simulate a selected motion when the user wearing the pair of step-up apparatuses travels by foot. In some embodiments, each of the step-up apparatuses substantially immediately collapses when a foot of the user transfers a substantial portion of the user's weight to the step-up apparatus and expands upon removal of the substantial portion of the user's weight without providing any appreciable propelling force. In certain embodiments, each of the step-up apparatuses collapses in less than about 1 second, 0.5 second, 0.1 second, or about 0.05 second after at least 25%, 50%, 75%, 90%, 95%, or all of the user's body weight (or mass) is supported by the apparatus. In some embodiments, the step-up apparatuses can have delay devices to ensure that a desired amount of the user's weight is supported by the apparatuses. The exercise apparatuses may thus begin to collapse after a desired delay period.
In other embodiments, an exercise device comprises an upper sole for supporting a foot of a user, a lower sole, and an actuating mechanism. The actuating mechanism movably couples the upper sole to the lower sole such that the exercise device is configurable between an expanded configuration and a collapsed configuration to define a maximum expansion distance. The actuating mechanism is operable to increase and/or decrease the maximum expansion distance of the exercise device. In some embodiments, the exercise device includes a controller operable to set the maximum expansion distance. The controller can adjust the maximum expansion distance based on signals from one or more sensors of the exercise device and/or based on user input.
In some embodiments, an exercise device comprises a sole assembly configured to support a user. The sole assembly includes an actuating mechanism operable to move the sole assembly from a collapsed configuration to an expanded configuration. In certain embodiments, the actuating mechanism has a first state of operation to provide a first rate of collapse and a second state of operation to provide a second rate of collapse that is different from the first rate of collapse.
In some embodiments, a system comprises a pair of exercise devices that can be opened and closed. An open exercise device can support most or substantially all of the user's body weight. In some embodiments, the open exercise device can support at least 60%, 80%, 90%, or 95% of the user's body mass without closing an appreciable amount. The user can stand on one foot, which is supported by the exercise device, as the exercise device closes. The user can operate the exercise devices to repeatedly raise and lower the user's body (e.g., the user's torso) to exercise. The distance the user's body is raised can be generally equal to the distances the exercise devices expand from a closed configuration to an open configuration. The exercise devices can be independently operated. For example, one exercise can close while the other exercise device opens.
In some embodiments, a method comprises stepping onto a pair of step-up apparatuses worn on feet of a user to move each step-up apparatus is between an expanded configuration and a compressed configuration. Each of the step-up apparatuses is expanded from the compressed configuration to the expanded configuration. In some embodiments, one of the step-up apparatus is moved from the expanded configuration and the compressed configuration while the other step-up apparatus is in the compressed configuration. The step-up apparatuses can move from the expanded configuration to the compressed configuration in more than about 0.05 second.
Non-limiting and non-exhaustive embodiments are described with reference to the following drawings, wherein like reference numerals refer to like parts or acts throughout the various views unless otherwise specified.
The present detailed description is generally directed to exercise systems that can provide different types of routines, exercises, and motions. The system can be used to simulate climbing steps, climbing up a slope, traversing uneven surfaces, and the like. Many specific details and certain exemplary embodiments are set forth in the following description and in
The exercise devices 130 tend to move from the closed configurations to the open configurations without any significant intervention by the user. The closed exercise device 130b, for example, can be lifted away from the support surface 133 to allow the exercise device 130b to self-expand. As the foot 132b is raised, the exercise device 130b automatically moves towards the open configuration.
The exercise devices 130 can be worn in a wide range of settings, including, without limitation, indoor settings, outdoor settings, or the like to travel by foot over different types of terrain to simulate traveling up a slope, stairs, and other uneven surfaces so as to enhance aerobic exercise, muscle tone, muscle building, and/or strength training. The exercise devices 130, for example, can be worn while stepping in place, walking, running, jogging, or performing other normal physical activities and can target certain muscles and can increase or decrease impact forces and/or level of intensity.
With continued reference to
The foot retainer 134 includes a plurality of coupling members 140a, 140b (collectively 140), illustrated in the form of straps that can be opened or closed. The coupling members 140 can be configurable between a foot retaining configuration of
The lower sole 160 is generally parallel to the upper sole 162. If the lower sole 160 rests on a horizontal surface, the upper sole 162 can be in a substantially horizontal orientation. The soles 160, 162 can remain substantially parallel as the sole assembly 138 expands and collapses. The orientations and relative positions of the lower and upper soles 160, 162 can be selected based on the desired position of the user's foot with respect to the ground.
The upper sole 162 includes a toe support region 150, a heel support region 152, and a central region 154 extending between the toe support region 150 and the heel support region 152. The toe support region 150 is positioned to be directly beneath the user's toes. The heel support region 152 is positioned to be directly beneath the user's heel. The upper sole 162 further includes a substantially flat surface 156 upon which the user 100 stands. Tread or other types of surface treatments for enhancing traction can be provided on the surface 156.
When a downwardly directed force is applied to the upper sole 162, the actuating mechanism 164 can be collapsed at a selected rate. The actuating mechanism 164 can include various types of mechanical devices that provide relative movement between the lower and upper soles 160, 162. For example, one or more biasing members, pneumatic cylinders, hydraulic devices, electromechanical systems, dampeners, piston devices (e.g., piston type members that extend and contract when the exercise device opens and closes), energy absorbers, and other types of devices (e.g., air and/or liquid filled devices) can allow such movement.
Referring to
Referring to
Pivoting mechanisms 178, 236 (see
Referring to
The guide assembly 262 is generally similar to the guide assembly 244 except as detailed below. The guide assembly 262 of
The stop 330 can be a generally rectangular member positioned within a rectangular window 450 (see
The stop 370 of
Pins 400, 402 physically engage and position the levers 310, 312, respectively. In some embodiments, including the illustrated embodiment of
The step-up height can be increased or decreased to increase or decrease the intensity of the aerobic activity. For a relatively strenuous workout for strengthening muscles, the step-up height can be more than about 5 inches. For a less strenuous workout with high aerobic activity, the step-up height can be less than about 5 inches (12.7 cm). The adjustment mechanism 300 (see
When a user applies a force F to the expanded sole assembly 138 to overcome the bias (e.g., a restoring force) provided by the opener assembly 247, the sole assembly 138 begins to collapse. The restoring force can be small enough to allow the sole assembly 138 to completely collapse but can be large enough to cause expansion of the sole assembly 138 when the sole assembly 138 is unloaded. In contrast to traditional spring shoes, the sole assembly 138 can be fully collapsed without generating an appreciable restoring force. The restoring force, if any, can be less than about 50%, 20%, 10%, 5%, or 2% of the maximum resistive force. As such, the sole assembly 138 does not provide any significant propelling force that can noticeably push a user away from the ground. Because the sole assembly 138 does not provide any appreciable propelling forces (e.g., forward and/or upward forces), the user has to lift his/her leg to move a foot and/or the exercise device. The roller assemblies 251, 338 translate forwardly in a direction (see arrows 460, 462) that is generally parallel with longitudinal axes of the lower and upper soles 160, 162. The axes of rotation 223, 221 are moved away from each other and the axes of rotation 220, 221 are moved away from each other as the sole assembly 138 collapses.
The opener assembly 247 can bias the sole assembly 138 to the expanded configuration. The upper sole 162 can translate away from the lower sole 160 as the biasing members 246, 248, 364, 366 (see
The pressurization device 520 can include, without limitation, one or more compressors, pumps, valves (e.g., gate valves, check valves, duck bill valves, globe valves, ball valves, or the like), or other components that can cooperate to control operation of the energy absorber 510. The pressurization device 520 is coupled to a main body 522 of an upper sole 525. In other embodiments, the pressurization device 520 is incorporated into or coupled to the energy absorber 510, or other component of the exercise device 500.
With continued reference to
The controller 504 can generally include, without limitation, one or more central processing units, processing devices, microprocessors, digital signal processors (DSP), application-specific integrated circuits (ASIC), readers, and the like. To store information, the controller 504 can also include, without limitation, one or more storage elements, such as volatile memory, non-volatile memory, read-only memory (ROM), random access memory (RAM), and the like. The controller 504 can be programmed based on the desired exercise programs to be performed. The controller 504 can store one or more programs for controlling the operation of a sole assembly 502. The input device 538 can also be used to switch between different programs, modes of operation, or the like. Different programs can be used to perform different types of activities (e.g., walking, running, jogging, or the like), different simulations (e.g., climbing stairs, walking on sand or gravel, or the like), control exercise intensity, target desired muscles (e.g., quadriceps, hamstrings, gluteal muscles, hip flexors, calves, or the like), or to achieve certain criteria (e.g., target heart rate, adjust supination/under-pronation, or the like). The controller 504 can control parameters of operation (e.g., rate of collapse, rate of expansion, distance of travel, orientations of the upper and lower soles, or the like). For example, the rate at which the exercise device 500 collapses when the user's body is raised onto the extended exercise device 500 can be selectively increased or decreased. In some embodiments, the exercise device 500 can provide a delayed collapse and/or a selected distance of vertical travel, such as about 2 inches to about 8 inches (about 5 cm to about 20.3 cm) of travel.
The controller 504 can generate a wide range of data, programs, or settings (e.g., force settings, height settings, or the like) used to control the exercise device. To calibrate the exercise device 500, the user can wear the exercise device 500 so that sensors send signals to the controller 504. The signals are used to determine force settings, generate control maps or curves (similar to the force curves and height curves shown in
If multiple users use the exercise device 500, the exercise device 500 can run unique programs for each user. The exercise device 500 can be recalibrated at any time to enhance performance. Calibration programs can be used to calibrate based at least in part on forces applied by the user, characteristics of motion (e.g., length of stride, cadence, or the like), characteristics of the user (e.g., weight, height, flexibility, etc.), and other exercise parameters.
The shoe main body 552 can be made, in whole or in part, of natural materials (e.g., leather, natural rubber, cloth, or the like), plastics, polymers, metals, composites, combinations thereof, or other materials suitable for surrounding the users foot. In some embodiments, the shoe main body 552 is made of pliable leather that conforms closely to a users foot for enhanced comfort. In other embodiments, the shoe main body 552 is made of a generally rigid plastic that appreciably limits relative movement of the user's ankle and can therefore provide enhanced support to ensure that the user's body is properly positioned with respect to the exercise device 550
A controller 620 embedded in the lower sole 604 can be programmed remotely via a wireless network. The controller 620 is communicatively coupled to drive devices 630, 632 (see
Referring to
The control mechanism 730 includes a rod 733 and an energy absorber in the form of a brake assembly 735. A pin 734 (shown in dashed line) of a rotatable handle 737 bears against the rod 733 slidably disposed in a through-hole 739 in a shoe main body 741. The pin 734 has external threads that mate with internal threads of a hole in the shoe main body 741 such that the end of the pin 734 moves towards or away from the rod 733 as the handle 737 rotates.
The rod 733 is fixedly coupled to the lower sole 754. The rod 733 extends upwardly away from the lower sole 754 and at least partially through the upper sole 752. When the exercise device 710 moves towards the closed configuration, the pin 734 frictionally slides along the rod 733. The frictional interaction provides the resistive force that controls the rate of collapse. To increase or decrease the resistive force, the compressive forces between the pin 734 and rod 733 can be increased or decreased.
Referring to
In some embodiments, the stop 773 is in the form of a pin assembly, a clamp, or the like. If the stop 773 includes a pin assembly, the rod 776 can include an array of through holes for receiving a pin of the stop 773. The pin can be positioned in different holes of the rod 776. If the stop 773 includes a clamp, the clamp may be movable between an open configuration for sliding along the rod 776 and a closed configuration for fixedly coupling the stop 773 to the rod 776.
The adjustment mechanism 771 can change a maximum expansion distance of the exercise device 775. The maximum expansion distance can be the distance the upper sole 777 travels when the exercise device 775 moves from a collapsed configuration to an expanded configuration. In some embodiments, the external threaded section 785 of the rod 776 can have a longitudinal length of about 2 inches such that the adjustment mechanism 771 can change the maximum expansion distance about 2 inches. In other embodiments, the adjustment mechanism 771 can change the maximum expansion distance at least 3 inches, 4 inches, 5 inches, 6 inches, or ranges encompassing such lengths.
Adjustment mechanisms can be at other locations and orientations. For example,
A force curve 840 of
At tc, the exercise device begins to collapse because the force 800 applied by the user is greater than the resistive force 840. The force required to initiate closing of the exercise device can be set by the user or may be determined by a controller. In some embodiments, tc, can be equal to or greater than about 0.05 second, 0.1 second, 0.2 second, or 1 second. For example, tc can be in the range of about 0.1 second to about 0.5 second. Most or substantially all of the user's body mass can be supported by the exercise device as the exercise device begins to close. The percentage of the user's body mass supported by the exercise device that causes movement of the device can be selected based on the desired motion. In some embodiments, at least 95% of the user's body mass is supported by the exercise device before a distance between the lower sole and the upper sole is appreciably decreased. In some embodiments, at least 90%, 80%, or 50% of the user's body mass is supported by the exercise device before the exercise device is closed half way.
A portion of the curve 840 (e.g., the portion of the curve 840 between t2 and t4) can be offset from the curve 800 to provide a generally constant acceleration. The rate of collapse can thus increase as the user's foot approaches the ground. For example, height curve 849 in
As shown in
To minimize, limit, or substantially prevent any appreciable sudden forces as the exercise device reaches the fully collapsed configuration, a cushioning member can be positioned between the upper and lower soles. The cushioning member can be made of foam or other highly compressible material. In some embodiments, cushioning members are coupled to an upper surface of the lower sole using adhesives.
Different types of mechanisms can be used to obtain the height curves 950, 960 of
Referring again to
In operation, a user can step onto an exercise device without any noticeable collapsing of an exercise device to enhance the user's stability. For example, a user with a body mass of about 70 kg can step onto the exercise device without having the exercise device close more than about 10%. If the exercise device has a range of travel of about 8 inches, the exercise device closes less than about 0.8 inch. After most of the user's body mass is carried by the exercise device, the device moves to the closed configuration.
At t0 to tc, the curve 960 slightly decreases. As the user stands on the exercise device, the exercise device can close slightly to reduce or limit stresses applied to the user's joints. When the user's weight has been applied to the exercise device at tc, the device can close at a higher rate of collapse.
A wide range of different types of energy absorbers can be used with the exercise devices disclosed herein. Energy absorbers can have integral delay mechanisms. Delay mechanisms can be mechanical devices, electromechanical devices, or the like. In some embodiments, the energy absorbers have different states of operation to provide different forces to control movement of the exercise devices.
Referring to
The outer housing 1130 includes a positioning device 1170 for inhibiting movement of the element 1142 and a positioning device 1172 for inhibiting movement of the element 1140. The positioning devices 1170, 1172 can include, without limitation, latches, gates, movable pins, or other types of devices that can hold and release the elements 1142, 1140.
The biasing member 1150 of
The positioning devices 1170, 1172 can be generally similar to each other and, accordingly, the description of one of the positioning devices applies equally to the other, unless indicated otherwise. The positioning devices 1170, 1172 may include pins that move inwardly and outwardly with respect to the housing 1130. In some embodiments, the positioning device 1172 is in the form of a hinged element that swings inwardly and outwardly in response to forces applied to the element 1140. For example, the hinged element can move to a closed position (e.g., when the hinged element extends generally perpendicularly to a longitudinal axis of the housing 1130) to hold the switch 1160 in a depressed position. The element can swing towards a sidewall of the housing 1130 to allow the switch 1160 to return to the extended position.
Referring to
The piston assembly 1114 can provide a wide range of different resistance profiles. In some embodiments, the resistance profiles vary during compression. For example, the piston assembly 1114 can provide forces that can increase significantly as the piston assembly 1114 reaches a fully compressed position. As the exercise device reaches its compressed position, the piston assembly 1114 can rapidly reduce the rate of collapse of the exercise device. In some embodiments, the piston assembly 1114 may be adjustable to provide various desired resistances, or resistance profiles.
As the exercise device moves towards the collapsed configuration, the element 1142 can return to its first position. A line 1192 is capable of pulling the element 1142 shown in
After the exercise device has collapsed, the user can pick up the exercise device to allow self-expansion. Once the exercise device has reached the desired step-up height, the positioning device 1172 can release the element 1140 of
The energy absorber 1110 of
The foot retainer 1200 includes a brace 1220 and a leg holder 1230 rotatably coupled to the brace 1220. An axis of rotation 1240 is defined by a pivot pin 1270 coupling the leg holder 1230 to the brace 1220. The brace 1220 and the leg holder 1230 cooperate to support the user's leg while allowing relative movement between the user's lower leg and the user's foot.
The leg holder 1230 includes a main body 1250 configured to accommodate at least a portion of a user's leg and a retainer 1252 (illustrated in the form of a strap) configured to surround and hold the user's leg against the main body 1250. When the user places an exercise device on the ground, the main body 1250 can be in a first position 1280 (shown in dashed line in
The brace 1220 can be an ankle support brace extending upwardly alongside a users ankle such that the axis of rotation 1240 is generally at a location where the user's foot bends when the user walks. For example, the axis of rotation 1240 is generally aligned with the user's ankle. The brace 1220 can be made, in whole or in part, of a rigid material, such as one or more metals, composites, plastics, or the like. In some embodiments, the brace 1220 is a metal brace made of aluminum or steel.
The foot retainer 1200 can further include a foot plate 1330 pivotally coupled to the upper sole 1202. The foot plate 1330 includes a toe support region 1340, a heel support region 1342, and a main body 1344 extending between the toe support region 1340 and the heel support region 1342. An axis of rotation 1210 can be positioned generally below the ball of the user's foot during use. The foot plate 1330 can therefore rotate as the user transfers weight from the heel to the ball of the foot. In other embodiments, the axis of rotation 1210 can be positioned anterior or posterior to the ball of the user's foot. For example, the axis of rotation 1210 can be positioned below the arch of the user's foot. The axis of rotation 1210 can also be at other locations, if need or desired.
A pin 1310 extends through a mount 1320 of the foot plate 1330 and a mount 1329 of the upper sole 1202 to define the axis of rotation 1210. The mounts 1320, 1329 and pin 1310 form a pivoting mechanism 1319. When the user steps onto the exercise apparatus, the heel support region 1342 can be pressed against an upper surface 1203 of the upper sole 1202. As the user transfers weight to the front of the foot, the foot plate 1330 rotates about the axis of rotation 1210 to bring the toe support region 1340 into contact with the upper surface 1203.
It should be noted that, as used in this specification and the appended claims, the singular forms “a,” “an,” and “the” include plural referents unless the context clearly dictates otherwise. It should also be noted that the term “or” is generally employed in its sense including “and/or” unless the content clearly dictates otherwise.
Various methods and techniques described above provide a number of ways to carry out the invention. Of course, it is to be understood that not necessarily all objectives or advantages described may be achieved in accordance with any particular embodiment described herein. Thus, for example, those skilled in the art will recognize that the methods may be performed in a manner that achieves or optimizes one advantage or group of advantages as taught herein without necessarily achieving other objectives or advantages as may be taught or suggested herein.
The exercise apparatus disclosed herein can be worn to provide a workout that is appreciably similar to the workout provided by climbing stairs or using a stair master machine. For example, a user can wear the apparatus indoors while performing everyday chores and activities. In outdoor applications, the user can wear the device on generally flat surfaces that can be found at shopping centers, malls, parks, sidewalks, or the like. The apparatuses can provide a motion that generally simulates climbing stairs to provide a vigorous workout even though the user is traveling across these generally flat surfaces. Of course, the apparatuses can be worn while traveling along uneven surfaces (e.g., while hiking) and on relatively steep inclines or declines. Traveling is broadly construed to include, without limitation, walking, running, jogging, or the like. In some embodiments, the exercise apparatuses can be used in aerobic classes. For example, a user can lock one exercise device in an extended configuration and the other exercise device in a collapsed configuration to perform step-up routines. The user can then step in place.
Furthermore, the skilled artisan will recognize the interchangeability of various features from different embodiments disclosed herein. Similarly, the various features and acts discussed above, as well as other known equivalents for each such feature or act, can be mixed and matched by one of ordinary skill in this art to perform methods in accordance with principles described herein. Additionally, the methods which are described and illustrated herein are not limited to the exact sequence of acts described, nor are they necessarily limited to the practice of all of the acts set forth. Other sequences of events or acts, or less than all of the events, or simultaneous occurrence of the events, may be utilized in practicing the embodiments of the invention.
Although the invention has been disclosed in the context of certain embodiments and examples, it will be understood by those skilled in the art that the invention extends beyond the specifically disclosed embodiments to other alternative embodiments and/or uses and obvious modifications and equivalents thereof. Accordingly, it is not intended that the invention be limited, except as by the appended claims.
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